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Manuscript ID : JEST-1610-3101 (R1) Visit : 128 Page: 375 - 387

10.22034/jest.2019.21920.3101

Article Type: Original Research

Proper Orthogonal Decomposition Performance to Determine the Inputs to the Artificial Neural Network for Prediction of Inflow into Alavian Dam

Subject Areas : Water Resource Management

Saber Moazami 1 , Roohollah Noori 2 , Mohammad Reza Vesali Naseh 3 , Abbas Akbarzadeh 4

1 - Assistant Professor, Civil Engineering, Environmental Science Research Center, Eslamshahr Branch, Islamic Azad University, Tehran, Iran.
2 - Assistant Professor of Environmental Engineering, Department of Civil Engineering, Arak University, Arak, Iran. *(Corresponding Author)
3 - Assistant Professor of Environment, Water Research Institute, Ministry of Energy, Tehran, Iran.
4 - Assistant Professor of Environmental Engineering, Graduate Faculty of Environment, University of Tehran, Tehran, Iran.

Received: 2016-10-30 Accepted : 2017-05-17 Published : 2020-09-22

Keywords: Monthly Inflow, Alavian Dam, Proper Orthogonal Decomposition, Artificial Neural Network,

Abstract :

Background and Objective: Dams play an important role in development of countries by drinking and agricultural water supply, flood control, hydropower energy supply and recreational purposes. Constructing a dam and making an artificial lake has an important effect on surrounding environment, so being able to forecast the inflow to the dam is an important issue for water resource management. Method: In this study artificial neural network (ANN) was applied to forecast the monthly inflow from Soofichai River to Alavian Dam. Regarding the huge amount of input data to ANN model and for optimizing its application, proper orthogonal decomposition (POD) was used in order to determine the best inputs for ANN model . Finally, the application of ANN and POD-ANN models was evaluated by determination coefficient (R2), mean absolute error (MAE) and average of absolute relative error (AARE). Findings: Results of ANN and POD-ANN models indicated that although ANN output is close to the observed values of inflow to the dam, but it has significant errors. POD-ANN model showed better results than ANN model for high values of inflow. In generall, comparing R2, MAE and AARE values of two models revealed that POD-ANN model had better performance in both calibration and verification steps in comparison with ANN model. R2, MAE and AARE in verification step of POD-ANN model were 0.93, 0.79, and 0.54, respectively. Discussion and Conclusion: Preprocessing data contributes to better performance of  POD-ANN than ANN model, especially in high values of inflow. Therefore, it can be concluded that applying data preprocessing and reducing inputs to ANN model enhances its performance.

References:


  1. Noori, R., Karbassi, A.R., Moghaddamnia, A., Han, D., Zokaei-Ashtian, M.H., Farokhnia, A. (2011). Assessment of input variables determination on the SVM model performance using PCA, Gamma test, and forward selection techniques for monthly stream flow prediction. Journal of Hydrology 401(3): 177-189.
    2.
  2. Zhang, B., Govindaruja, R.S. (2000). Prediction of watershed runoff using Bayesian concepts and modular neural networks. Water Resources Research 36(3): 753-762.
    3.
  3. Nayak, P.C., Sudheer, K.P., Rangan, D.M., Ramasastri, K.S. (2004). A neuro-fuzzy computing technique for modeling hydrological time series. Journal of Hydrology 291: 52-66.
    4.
  4. Lin, J.Y., Cheng, C.T., Chau, K.W. (2006). Using support vector machines for long-term discharge prediction. Hydrological Sciences Journal 51(4): 599-612.
    5.
  5. He, Z., Wen, X., Liu, H., Du, J. (2014). A comparative study of artificial neural network, adaptive neuro fuzzy inference system and support vector machine for forecasting river flow in the semiarid mountain region. Journal of Hydrology 509: 379-386.
    6.
  6. Noori, R., Asadi, N., Deng, Z. (2018). A simple model for simulation of reservoir stratification. Journal of Hydraulic Research 57(4):561-572. DOI:10.1080/00221686.2018.1499052
    7.
  7. Ravindran, S.S. (2000). A reduced-order approach for optimal control of fluids using proper orthogonal decomposition. Int. J. Numer. Methods Fluids 34: 425-448.
    8.
  8. Noori, R., Tian, F., Berndtsson, R., Abbasi, M.R., Naseh, M.V., Modabberi, A., Soltani, A., Kløve, B. (2019). Recent and future trends in sea surface temperature across the Persian Gulf and Gulf of Oman. PloS One 14(2):p.e0212790. DOI:10.1371/journal.pone.0212790.
    9.
  9. Noori, R., Yeh, H.D., Ashrafi, K., Rezazadeh, N., Bateni, S.M., Karbassi, A., Kachoosangi, F.T., Moazami, S. (2015). A reduced-order based CE-QUAL-W2 model for simulation of nitrate concentration in dam reservoirs. Journal of Hydrology 530: 645-656.
    10.
  10. Noori, R., Tian, F., Ni, G., Bhattarai, R., Hooshyaripor, F., Klöve, B. (2019). ThSSim: a novel tool for simulation of reservoir thermal stratification. Scientific Reports 9(1): 18524. DOI: 10.1038/s41598-019-54433-2.
    11.
  11. Noori, R., Abbasi, M.R., Adamowski, J.F. and Dehghani, M. (2017). A simple mathematical model to predict sea surface temperature over the northwest Indian Ocean. Estuarine, Coastal and Shelf Science 197: 236-243.
    12.
  12. Noori, R., Safavi, S. and Shahrokni, S.A.N. (2013). A reduced-order adaptive neuro-fuzzy inference system model as a software sensor for rapid estimation of five-day biochemical oxygen demand. Journal of Hydrology 495: 175-185.
    13.
  13. Noori, R., Karbassi, A., Ashrafi, K., Ardestani, M., Mehrdadi, N. and Bidhendi, G.R.N. (2012). Active and online prediction of BOD5 in river systems using reduced-order support vector machine. Environmental Earth Sciences 67: 141-149.
    14.
  14. Modabberi, A., Noori, R., Madani, K., Ehsani, A.H., Mehr, A.D., Hooshyaripor, F. and Kløve, B. (2020). Caspian Sea is eutrophying: the alarming message of satellite data. Environmental Research Letters 15(12):p.124047. DOI:10.1088/1748-9326/abc6d3.
    15.
  15. Haykin, S. (1994). Neural Networks: A Comprehensive Foundation. Prentice Hall, New Jeresy.
    16.
  16. Noori, R., Khakpour, A., Omidvar, B. and Farokhnia, A. (2010). Comparison of ANN and principal component analysis-multivariate linear regression models for predicting the river flow based on developed discrepancy ratio statistic. Expert Systems with Applications 37: 5856-5862.
    17.
  17. Coulibaly, P., Ancti, F., Bobee, B. (2000). Daily reservoir inflow forecasting using artificial neural networks with stopped training approach. Journal of Hydrology 230: 244-257.
    18.

 

 

 

 

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  1. Noori, R., Karbassi, A.R., Moghaddamnia, A., Han, D., Zokaei-Ashtian, M.H., Farokhnia, A. (2011). Assessment of input variables determination on the SVM model performance using PCA, Gamma test, and forward selection techniques for monthly stream flow prediction. Journal of Hydrology 401(3): 177-189.
    2.
  2. Zhang, B., Govindaruja, R.S. (2000). Prediction of watershed runoff using Bayesian concepts and modular neural networks. Water Resources Research 36(3): 753-762.
    3.
  3. Nayak, P.C., Sudheer, K.P., Rangan, D.M., Ramasastri, K.S. (2004). A neuro-fuzzy computing technique for modeling hydrological time series. Journal of Hydrology 291: 52-66.
    4.
  4. Lin, J.Y., Cheng, C.T., Chau, K.W. (2006). Using support vector machines for long-term discharge prediction. Hydrological Sciences Journal 51(4): 599-612.
    5.
  5. He, Z., Wen, X., Liu, H., Du, J. (2014). A comparative study of artificial neural network, adaptive neuro fuzzy inference system and support vector machine for forecasting river flow in the semiarid mountain region. Journal of Hydrology 509: 379-386.
    6.
  6. Noori, R., Asadi, N., Deng, Z. (2018). A simple model for simulation of reservoir stratification. Journal of Hydraulic Research 57(4):561-572. DOI:10.1080/00221686.2018.1499052
    7.
  7. Ravindran, S.S. (2000). A reduced-order approach for optimal control of fluids using proper orthogonal decomposition. Int. J. Numer. Methods Fluids 34: 425-448.
    8.
  8. Noori, R., Tian, F., Berndtsson, R., Abbasi, M.R., Naseh, M.V., Modabberi, A., Soltani, A., Kløve, B. (2019). Recent and future trends in sea surface temperature across the Persian Gulf and Gulf of Oman. PloS One 14(2):p.e0212790. DOI:10.1371/journal.pone.0212790.
    9.
  9. Noori, R., Yeh, H.D., Ashrafi, K., Rezazadeh, N., Bateni, S.M., Karbassi, A., Kachoosangi, F.T., Moazami, S. (2015). A reduced-order based CE-QUAL-W2 model for simulation of nitrate concentration in dam reservoirs. Journal of Hydrology 530: 645-656.
    10.
  10. Noori, R., Tian, F., Ni, G., Bhattarai, R., Hooshyaripor, F., Klöve, B. (2019). ThSSim: a novel tool for simulation of reservoir thermal stratification. Scientific Reports 9(1): 18524. DOI: 10.1038/s41598-019-54433-2.
    11.
  11. Noori, R., Abbasi, M.R., Adamowski, J.F. and Dehghani, M. (2017). A simple mathematical model to predict sea surface temperature over the northwest Indian Ocean. Estuarine, Coastal and Shelf Science 197: 236-243.
    12.
  12. Noori, R., Safavi, S. and Shahrokni, S.A.N. (2013). A reduced-order adaptive neuro-fuzzy inference system model as a software sensor for rapid estimation of five-day biochemical oxygen demand. Journal of Hydrology 495: 175-185.
    13.
  13. Noori, R., Karbassi, A., Ashrafi, K., Ardestani, M., Mehrdadi, N. and Bidhendi, G.R.N. (2012). Active and online prediction of BOD5 in river systems using reduced-order support vector machine. Environmental Earth Sciences 67: 141-149.
    14.
  14. Modabberi, A., Noori, R., Madani, K., Ehsani, A.H., Mehr, A.D., Hooshyaripor, F. and Kløve, B. (2020). Caspian Sea is eutrophying: the alarming message of satellite data. Environmental Research Letters 15(12):p.124047. DOI:10.1088/1748-9326/abc6d3.
    15.
  15. Haykin, S. (1994). Neural Networks: A Comprehensive Foundation. Prentice Hall, New Jeresy.
    16.
  16. Noori, R., Khakpour, A., Omidvar, B. and Farokhnia, A. (2010). Comparison of ANN and principal component analysis-multivariate linear regression models for predicting the river flow based on developed discrepancy ratio statistic. Expert Systems with Applications 37: 5856-5862.
    17.
  17. Coulibaly, P., Ancti, F., Bobee, B. (2000). Daily reservoir inflow forecasting using artificial neural networks with stopped training approach. Journal of Hydrology 230: 244-257.
    18.

 

 

 

 

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